Microsoft Word Interfacing adc to fpga V

Figure 2 – Block Diagram of Serial ADC Connections to the Lattice FPGA

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InterfacingAnalogtoDigitalConverterstoFPGAs

Figure 3 - Post-Route Timing Simulation Results Showing a Repeating Data Pattern

Figure 2 – Block Diagram of Serial ADC Connections to the Lattice FPGA
The sample design uses two shift registers to capture the data as it comes in from
the ADC. The first one is used to capture the data on the positive edge of the
OUTCLK signal and the second captures the data on the falling edge of OUTCLK.
The pre-engineered generic DDR I/O interface could be used in place of this logic to
capture the data on both edges of the clock. The user would then need a second
clock running at half the rate of the OUTCLK signal to transfer the data into the shift
registers from the DDR registers, 2 bits at a time.
The OUTCLK signal is specified as an Edge clock in order to handle the high-speed
clock coming from the ADC. For the 60 MSPS data rate in the single lane mode, the
clock rate would be 420 MHZ coming from the ADC. The edge clock in the
LatticeECP2/M and LatticeXP2 FPGAs can handle clock rates up to 420 MHZ.
The data from the shift registers is then transferred into the data word register upon
the FRAME signal rising edge. This data word register is stored in an EBR memory
block for reading out later. The Memory is designed to capture the first 512 samples
for reading out later to verify the operation of the design. A pseudo Dual Port RAM
module is implemented using EBR memory to store the data. This module is
generated using the IPexpress

tool of Lattice’s ispLEVER design software.

8
Interfacing Analog to Digital Converters to FPGAs
A Lattice Semiconductor White Paper
Figure 3 - Post-Route Timing Simulation Results
Showing a Repeating Data Pattern
In order to verify this sample design, a simulation was run using the ModelSim tools
provided with ispLEVER. These results are shown in Figures 3 and 4. In Figure 3,
the repeating data pattern used as an input can be seen as the value shown for the
dataout port. The dataout port is connected to the read port of the pseudo Dual Port
RAM module. The data is read out of memory when the read address is incremented
in the test-bench used for this simulation.
Figure 4 shows the timing relationship between the data input and the OUTCLK and
FRAME signals. Note that the FRAME signal has been shifted in the test-bench to
the position shown. This shows the relationship that is required at the maximum
clock rate to read the data accurately. In actual practice, a PLL or DLL would be
used to shift the FRAME signal to this alignment. Please see the
ADC14DS065/080/095/105 datasheet for the FRAME signal alignment that is output
from the ADC. The left cursor marks the beginning of a data frame. The right cursor
marks the beginning of the next data frame. There are seven OUTCLK periods in the
data frame for the 14 bits of data. The total data frame time shown is for an OUTCLK
rate of 417 MHz, which corresponds to a 59.5 MSPS data rate in one lane mode.

9
Interfacing Analog to Digital Converters to FPGAs
A Lattice Semiconductor White Paper
The input signal from the ADC is “data_sd0” and it can be seen that the value in this
frame is: 10 0100 1001 1001 This corresponds to a value of 9369, which is the
sixth value in the sequence as shown in figure 3.

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